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Novel High-Gain, Improved-Bandwidth, Finned-Ladder V-Band Traveling-Wave TubeSlow-Wave Circuit Design

机译：新型高增益，改进带宽，Finned-Ladder V波段行波管慢波电路设计

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The V-band frequency range of 59-64 GHz is a region of the millimeter-wavespectrum that has been designated for inter-satellite communications. As a first effort to develop a high-efficiency V-band Traveling-Wave Tube (TWT), variations on a ring-plane slow-wave circuit were computationally investigated to develop an alternative to the more conventional ferruled coupled-cavity circuit. The ring-plane circuit was chosen because of its high interaction impedance, large beam aperture, and excellent thermal dissipation properties. Despite these advantages, however, low bandwidth and high voltage requirements have, until now, prevented its acceptance outside the laboratory. In this paper, the three-dimensional electrodynamic simulation code MAFIA (solution of MAxwell's Equation by the Finite-Integration-Algorithm) is used to investigate methods of increasing the bandwidth and lowering the operating voltage of the ring-plane circuit. Calculations of frequency-phase dispersion, beam on-axis interaction impedance, attenuation and small-signal gain per wavelength were performed for various geometric variations and loading distributions of the ring-plane TWT slow-wave circuit. Based on the results of the variations, a circuit termed the finned-ladder TWT slow-wave circuit was designed and is compared here to the scaled prototype ring-plane and a conventional ferruled coupled-cavity TWT circuit over the V-band frequency range. The simulation results indicate that this circuit has a much higher gain, significantly wider bandwidth, and a much lower voltage requirement than the scaled ring-plane prototype circuit, while retaining its excellent thermal dissipation properties. The finned-ladder circuit has a much larger small-signal gain per wavelength than the ferruled coupled-cavity circuit, but with a moderate sacrifice in bandwidth.

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Kory, C. L.; Wilson, J. D.;
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年度 1994
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总页数 7
原文格式 PDF
正文语种 eng
中图分类工业技术;
关键词
Bandwidth; Cavities; Electric potential; Extremely high frequencies; High gain; Microwave circuits; Millimeter waves; Optimization; Ring structures; Traveling wave tubes; Applications programs (Computers); Computerized simulation; Electrical impedance; El;

机译：带宽;空腔;电位;极高频率;高增益;微波电路;毫米波;优化;环形结构;行波管;应用程序（计算机）;计算机模拟;电阻抗; El;

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专利

1. Novel high-gain, improved-bandwidth, finned-ladder V-band traveling-wave tube slow-wave circuit design [J] . Kory C.L., Wilson J.D. IEEE Transactions on Electron Devices . 1995,第9期

机译：新颖的高增益，带宽改进的，阶梯形V波段行波管慢波电路设计
2. Design of a re-entrant double-staggered ladder circuit for V-band coupled-cavity traveling-wave tubes [J] . 刘洋, 徐进, 赖剑强, 中国物理：英文版 . 2012,第007期

机译：V波段耦合腔行波管的重入式双交错阶梯电路设计
3. Design of a re-entrant double-staggered ladder circuit for V-band coupled-cavity traveling-wave tubes [J] . Liu Yang, Xu Jin, Lai Jian-Qiang, 中国物理：英文版 . 2012,第007期

机译：V波段耦合腔行波管的重入式双交错阶梯电路设计
4. Design of a V-band overmoded traveling-wave tube [C] . Zhou Jing, Sirigiri Jagadishwar R. IEEE International Vacuum Electronics Conference . 2014

机译：V波段过调制行波管的设计
5. High Performance Millimeter Wave Transceiver Circuits for V-Band Applications using Silicon Processes. [D] . Law, Chi Yiu. 2011

机译：使用硅工艺的V波段应用的高性能毫米波收发器电路。
6. Design and Analysis of a High-Gain and Robust Multi-DOF Electro-thermally Actuated MEMS Gyroscope [O] . Muhammad Saqib, Muhammad Mubasher Saleem, Naveed Mazhar, 2018

机译：高增益稳健的多自由度电热驱动MEMS陀螺仪的设计与分析
7. Novel high-gain, improved-bandwidth, finned-ladder V-band Traveling-Wave Tube slow-wave circuit design [O] . Wilson Jeffrey D., Kory Carol L. 1994

机译：新颖的高增益，带宽改进的鳍状V形行波管慢波电路设计

Novel High-Gain, Improved-Bandwidth, Finned-Ladder V-Band Traveling-Wave TubeSlow-Wave Circuit Design

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